advanced ignition control technology for hcci combustion
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Honda R&D Technical Review October 2014
Advanced Ignition Control Technology for HCCI Combustion
Kiminori KOMURA* Masanobu TAKAZAWA* Teruyoshi MORITA*
ABSTRACTSpark-Assisted HCCI combustion, which assists ignition by igniting direct injection spray with a spark, has been
proposed to help enable the practical realization of homogeneous charge compression ignition combustion, thereby achieving high thermal efficiency. This method increases the controllability of ignition, an issue of homogeneous charge compression ignition, and expands the range of ignition combustion by a maximum of three times compared to the conventional method.
The fuel efficiency of Spark-Assisted HCCI was verified, with results indicating a decrease of 16% in steady-state fuel consumption against cooled EGR combustion technology and a JC08 mode fuel efficiency simulation showing an increase of 4.5% in fuel efficiency.
1. Introduction
Given todays high level of concern towards global environmental issues, the automotive industry is being called on to develop technologies that will further reduce CO2 emissions in order to help to mitigate climate change and address the issue of depletion of fossil fuels. Because the realization of increased thermal efficiency can contribute to reducing CO2 emissions, research towards this end is being continuously conducted in a wide variety of fields by companies and university and other research institutes(1), (2). Homogeneous-Charge Compression Ignition (HCCI) technology makes it possible to stably combust lean air-fuel mixtures through auto-ignition of a homogeneous mixture. This reconciles a high theoretical thermal efficiency with low NOx emissions, and HCCI thus presents good prospects as a mode of combustion in future engines(3)-(6).
Figure 1 shows details of Hondas main HCCI initiatives up to the present. In 1999, Honda commenced fundamental research towards the realization of HCCI by increasing the compression temperature via Exhaust Gas Recirculation (EGR) realized by means of Negative
valve Overlap (NOL) in an engine with an electromagnetic variable valve timing system. This research increased efficiency and realized low NOx emissions in the low-load range. Using this technology in combination with inter-cylinder EGR boost, which introduces EGR using exhaust blowdown pressure from other cylinders, made it possible to extend the operating range into the medium-load range. Figure 2 shows examples of the operating range for HCCI when using NOL EGR and the expansion in the operating range realized by inter-cylinder EGR boost. Honda has proceeded with numerous other initiatives in this area of research, for example increasing the controllability of combustion through the use of dual fuels (introducing the use of alcohol fuels)(7)-(9).
However, this research is still at the concept engine level, and has not yet been practically realized. One of the main factors standing in the way of the practical realization of HCCI is the challenge represented by control of ignition timing to help enable continuous stable combustion. The authors therefore proposed Spark-Assisted HCCI (SA-HCCI) as a method of accurate ignition timing control, verified the combustion concept in the NOL range, and developed the necessary hardware.
* Automobile R&D Center
Technical papers
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Advanced Ignition Control Technology for HCCI Combustion
2. SA-HCCI Combustion Concept2.1. Merits of HCCI
HCCI is a type of homogeneous premixed combustion
in which high compression ratios and internal EGR realized using the methods shown in Fig. 1 increase the temperature of the mixture in the cylinders to approximately 1000 K at close to compression top dead center, causing a reaction in the entire mixture in the combustion chamber resulting in auto-ignition. By initiating combustion through auto-ignition, it becomes possible to employ lean combustion at the air-fuel ratio range of A/F25 and above, which represents a challenge in terms of the realization of combustion stability when spark ignition (SI) combustion, in which combustion is initiated by spark ignition, is used.
Making possible leaner combustion than SI by means of auto-ignition, HCCI displays high theoretical thermal efficiency and low pumping loss and time loss. In addition, because the combustion temperature is low, heat loss is low and NOx emissions are minimal. Given these merits, this combustion method can be expected to increase fuel efficiency by around 20% against stoichiometric SI, and at the same time will also be able to realize low emissions (EM).
Fig. 1 Research on HCCI at Honda
(a) NOL (1999-2004) Research using electromagnetic VVT mechanism
(b) Inter-cylinder EGR boost (2004-2012)
Crank angle TDC BDC
INEXValv
e lift NOL
0 500BMEP (kPa)
BSFC
(g/kW
h)
200
500
Stoichiometry
HCCINOx
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Figure 3 shows P-V diagrams for SI and HCCI with internal EGR realized by NOL in the same engine. HCCI is clearly able to minimize pumping loss and time loss.
However, HCCI also presents a number of issues that are barriers to its practical realization.
2.2. Issues of HCCI Three major issues of HCCI can be recognized. These
are:
(1) The operating range is narrow; (2) Combustion ignition control represents a challenge; and (3) Exhaust gas purification performance is poor in the lean
environment. With regard to Issue (1), the HCCI operating range,
despite the fact that the expansion of the range via inter-cylinder HCCI, as shown in Fig. 2, is able to extend it to largely cover JC08 mode, HCCI operation is not possible in the high-load, high-engine-speed range outside the mode. At present, therefore, it is not possible to cover the entire necessary engine operating range using HCCI alone.
Issue (2), ignition control, is an important issue for vehicles used in a wide range of environments.
Figure 4 shows a diagrammatic representation of the heat generation history for HCCI from the compression stroke to auto-ignition, including the mixture oxidation reaction process.
In HCCI combustion, a low-temperature oxidation reaction that produces a cool flame commences from a mixture temperature of around 600 K. The accumulation of formaldehyde and the proliferation of CO and OH radicals generates a blue flame, until finally a hot flame that generates CO2 from CO is produced. When employing SI combustion, in which the spark plugs advance the reaction rapidly and a hot flame is produced, ignition timing can be easily controlled by control of the spark timing of the plugs. In the case of HCCI, because changes in temperature and pressure during the compression stroke change the oxidation reaction process, control of ignition timing represents a challenge. To help ensure stable combustion in a variety of environments, it will be necessary to accurately control ignition timing, and attempt to reliably prevent misfires,
torque fluctuations, and increases in emissions. With regard to after-treatment, Issue (3), the temperature
of exhaust gas generated by HCCI is lower at the exhaust manifold outlet than stoichiometric SI exhaust gas. At an indicated mean effective pressure (IMEP) of 400 kPa, HCCI exhaust gas is around 320C, compared to 500C for SI. In addition, because combustion is lean, clearing EM regulations via the conventional method of employing a three-way catalyst (TWC) also represents a challenge. This makes a new after-treatment system essential.
Of these issues, it is the controllability of ignition, Issue (2), that it is particularly necessary to address, or it will not be possible to employ HCCI in automotive engines. The research discussed in this paper focused on this issue of controllability of ignition.
2.3. Concept of SA-HCCI Combustion As discussed above, in order to realize stable ignition
timing, which represents one of the issues of HCCI, a method has been tested in which auto-ignition is assisted by a miniscule combustion event (trigger flame) generated by igniting a miniscule amount of directly injected fuel via the spark plug. Figure 5 shows the differences in the method of increasing temperature in the cylinders and the heat release history for conventional HCCI and SA-HCCI. In the majority of cases, standard HCCI increases temperature by means of internal EGR and pressure in order to induce auto-ignition of the lean, homogeneous mixture. By contrast, in SA-HCCI, a small amount of fuel is directly injected towards the spark plug during the compression stroke, and the propagation of a flame by the spark plug increases temperature, inducing auto-ignition. The heat release history for SA-HCCI shows that by contrast with conventional HCCI, a trigger flame releases heat prior to auto-ignition. Because the position of the combustion center of gravity for the realization of increased thermal efficiency is close to 10 deg ATDC, as in the case of SI and conventional HCCI, the aim was to realize combustion with a heat release history in
Fig. 3 Comparison of cylinder pressure Fig. 4 Oxidation reaction process for HCCI
10
100
1000
10000
10 100 1000
Cylin
der p
ress
ure
(kPa)
Volume (cm3)
HCCISI
Low time loss
Low heat loss
Low pumping loss
Rat
e of
hea
t rel
ease
Coolflame Blue flame
Hot flame
Time
HCHO HO2 OH
CO2CO
Start ofoxidation reaction
Oxidation reaction and decomposition reactionbalance
Ignition delay(Cool flame Hot flame)
Rapid combustion
Dependent on temperature,pressure, and concentration
Ignition
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Advanced Ignition Control Technology for HCCI Combustion
which auto-ignition occurred at close to 2 deg ATDC. At the same time, because the trigger flame is propagated
by spark ignition, it is necessary to set the conditions for the trigger flame fuel injection at close to stoichiometric conditions. Therefore, the trigger flame combustion temperature is high, and NOx is locally produced. Figure 6 shows the results of shadowgraph visualization of the
ignition process for HCCI and SA-HCCI. This shows the process of induction of auto-ignition by flame propagation via direct injection in SA-HCCI.
3. Technologies Required for Realization of SA-HCCI
3.1. Setting of Trigger Flame The setting of the trigger flame is an important factor
for SA-HCCI. It was necessary to set the trigger flame with consideration of the following: (1) Required calorific value for trigger flame;(2) Spray distance for arrival at plug (penetration); and (3) Restriction of NOx emissions.
These factors will each be discussed in detail below.
3.1.1. Required calorific value for trigger flame It is necessary to realize a calorific value for the trigger
flame that will cause the mixture to burst into a hot flame. The necessary calorific value was back-calculated
from the target heat release history, and was set with consideration of realization of a flame propagation speed that made it possible to achieve the temperature for auto-ignition at close to 2 deg ATDC. Figure 7 shows an in-cylinder temperature history at an engine speed (Ne) of 1500 rpm and an IMEP of 350 kPa. The necessary gas temperature for ignition of the mixture was approximately 1070 K, and it was not possible to realize this temperature via the temperature rise due to internal EGR and piston compression. Because of this it would be necessary to realize the target temperature following a temperature increase of approximately 50 K, realized by combustion of a directly injected mixture. With 375 cm3 as the precondition for each cylinder, the necessary level of trigger flame heat for a temperature increase of 50 K would be approximately 10 J per cylinder.
3.1.2. Penetration to reach plug Because the stratified mixture that would generate the
trigger flame would be ignited by the spark plug, it was essential for the DI spray to arrive at the plug. If the fuel flow rate for the trigger flame was insufficient, the spray
Fig. 6 Visualization of combustion chamber by shadowgraph method
-60 deg ATDC -60 deg ATDC
-30 deg ATDC -30 deg ATDC
-20 deg ATDC -20 deg ATDC
0 deg ATDC 0 deg ATDC
5 deg ATDC 5 deg ATDC
Spark plug
DI
Spray
Trigger flame
Auto-ignition
(b) SA-HCCI(a) HCCI
Combustion chamber
Auto-ignition
900
950
1000
1050
1100
-60 -50 -40 -30 -20 -10 0 10
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ylind
er g
as te
mpe
ratu
re (K
)
Crank angle (deg)
Rise of t
emperat
ure by
compres
sion
Rise of t
emperat
ure by
compres
sion
Auto-ignition temperatureAuto-ignition temperature
Target: Commencement of main combustion at approx. 2 deg
Target: Commencement of main combustion at approx. 2 deg
50 K50 K
Target: MFB50% at approx. 10 degTarget: MFB50% at approx. 10 deg
Rise of t
emperat
ure
by trigg
er flame
Rise of t
emperat
ure
by trigg
er flame
Fig. 7 Temperature rise process for SA-HCCI
Fig. 5 SA-HCCI
Port injector
1100 1100
1000
900
800
700
1000
900
800
700
Homogeneous leanAuto-ignition
ecttotooror
Homogeneous lean
Port injector
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ectctor
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Compre-ssion
InternalEGR
Auto-ignitiontemperature
Auto-ignitiontemperature
Com
pres
sion
tem
pera
ture
(K)
Com
pres
sion
tem
pera
ture
(K)
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10
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30
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-30 300Rat
e of
hea
t rel
ease
(J/de
g)
Crank angle (deg)
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HCCISA-HCCI
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Compression Trigger flame Main combustion
Auto-ignition
(a) HCCI (b) SA-HCCIDI: Direct Injector
Compre-ssion
InternalEGR
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Honda R&D Technical Review October 2014
would possess inadequate penetration, and depending on the distance between the plug and the direct injector, the spray would not arrive at the plug.
Figure 8 shows results for the relationship between the distance between the direct injector and the plug and DI fuel energy enabling ignition.
The calorific value of the trigger flame to help ensure ignition (the flow rate of the DI spray) is determined by the distance between the direct injector and the spark plug. However, when the calorific value of the trigger flame increases, NOx emissions also increase. When the distance between the direct injector and the spark plug is set at 30 mm, the level of heat generation by the trigger flame to help ensure penetration is 20 J per cylinder.
3.1.3. Restriction of NOx emissions Increasing the calorific value of the trigger flame would
increase the controllability of ignition, but NOx emissions would also increase, and the benefit of lean burn would be lost. Figure 9 shows the relationship between the calorific value of the trigger flame and NOx emissions.
The allowable level of NOx emissions varies based on the engine type and EM regulations. Assuming an engine displacement of 1.5 L, in order to realize a reduction in NOx emissions of 75%, as specified by Japans Post New Long-Term Regulation, it would be necessary to control
emissions to an upper limit of approximately 0.12 mg/s. At an Ne of 1500 rpm and an IMEP of 350 kPa, the upper limit for the calorific value of the trigger flame would therefore be 25 J per cylinder.
3.1.4. Summary of setting of trigger flame Figure 10 shows the method of setting the trigger
flame, with the temperature of the gas in the cylinders as the benchmark.
10 J was set as the minimum calorific value necessary for the supplied homogeneous lean air-fuel mixture to auto-ignite and produce a hot flame. A further 20 J was added as corresponding to the flow rate necessary to help ensure that the DI spray would arrive at the spark plug. The range from 20 J to 25 J, the upper limit value for NOx emissions, was therefore established as the range of setting values for the trigger flame. The calorific value above the 10 J necessary for the trigger flame represents a temperature margin, and is available to make it possible to absorb variations in environmental conditions and amount of control.
3.2. SA-HCCI System Configuration Figure 11 shows the necessary system configuration for
the practical realization of the SA-HCCI concept. For (1) in the figure, internal EGR control, a variable
Fig. 9 Relationship between DI fuel energy and NOx
Fig. 10 Method of setting trigger flame
0
0.1
0.2
0.3
0 10 20 30 40 50 60
NO
x (m
g/s)
DI fuel energy (J)
Target of project=0.12 mg/sTrigger flame calorific value=25 J/cylinder(JC08)
Target of project=0.12 mg/sTrigger flame calorific value=25 J/cylinder(JC08)
920
960
1000
1040
1080
0 5 10 15 20 25 30
Cylin
der t
empe
ratu
re (K
)
DI fuel energy (J)
50 K
Minimum required NOx limit
130 K
Penetration
Setting range of trigger flame
100 K
Auto-ignition temperature
Rise oftemperature
by triggerflame
Temperature increaseby compression
Minimum required temperature
Fig. 11 SA-HCCI system configuration
Low-temperature catalystNOx catalyst
Injector withcylinder pressure sensor
Feed-forward control(Plant model)
Variable value systems
PI+DI fuel system
Feed-back control(Cylinder pressure feedback)
Cylinder pressure sensor
EM
Tem
pera
ture
of g
as (K
)
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InternalEGR
Compression
Target temperature
Temperature of
compression
700
800
900
1000
1100
(4) After-treatment
(3) Combustion feedback control(1) Internal EGR control
(2) Trigger flame control
Fig. 8 Relationship between DI flow and DI penetration
0
10
20
30
40
50
DI f
uel e
nerg
y (J)
0
0.1
0.2
0.3
0.4
10 15 20 25 30 35 40 45
NO
x (m
g/s)
L: Distance between DI and plug (mm)
LL
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Advanced Ignition Control Technology for HCCI Combustion
valve system making it possible to change the intake (IN) and exhaust (EX) valve timing is necessary. As Fig. 12 shows, the amount of internal EGR can be appropriately controlled in response to load by varying NOL via Valve Timing Control (VTC) employing IN and EX cams.
For (2) in the figure, trigger flame control, two injection systems are necessary: A low flow-rate direct injector to produce the trigger flame, and a port injector for control of load. Precise specification of the flow rate at a low level is necessary for the direct injector for the trigger flame. The reason for this is that because the injector cannot provide the dynamic range necessary to cover fuel injection amounts across the entire load range, and injection is highly oriented towards the direction of the spark plug, there are concerns that injection of too much fuel would cause combustion to become unstable.
In-cylinder pressure sensors are necessary for feedback combustion control, (3) in the figure. The state of the mixture is estimated based on the values measured by the in-cylinder pressure sensors, and ignition timing control is precisely applied with the amount of internal EGR calculated from operating conditions and the calorific value and injection timing necessary for the trigger flame as parameters. The use of in-cylinder pressure sensors built into the direct injectors(10) was made a prerequisite.
For (4) in the figure, after-treatment, an HC purification catalyst to respond to the low exhaust temperatures of lean combustion and an NOx purification catalyst to make it possible to broaden the HCCI combustion range are necessary.
This paper will not discuss details of after-treatment and combustion control.
Table 1 Engine specificationsNumber of cylinders 4 Displacement [cm3] 1500Bore Stroke [mm] 73 89.4Compression ratio 14
Valve train IN EX VTEC and VTCGasoline 91RON
temperature was varied by varying the amount of internal EGR. The combustion range was defined as a combustion fluctuation rate of 4% or less and a pressure rise rate (dP/dq ) (an index of combustion noise) of 400 kPa and below. The combustion range within which standard HCCI satisfied the conditions above was a narrow range between EGR rates of 50% and around 53% (the difference in in-cylinder gas temperature at this time was around 6 K). In the case of SA-HCCI, despite the fact that the EGR rate was lowered and the in-cylinder temperature was reduced, the advancement of the trigger flame ignition timing and the increase in the combustion amount for the trigger flame made it possible to realize continuous combustion in the range above an EGR rate of 10% (in-cylinder temperatures of 20 K and above).
Fig. 13 Concept verification
0
0.1
0.2
0.3
0.4
NO
x (m
g/s)
SA-HCCIHCCI
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10
20
30
40
50
Igni
tion
timin
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g)
100
200
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dP/d
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a/deg
)
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8
42 44 46 48 50 52 54 56
Coef
ficie
nt o
f va
rianc
e of
IMEP
(%)
Internal EGR ratio (%)
Limit=4%
Limit=400 kPa/deg
About 4 K
Fig. 12 Variable valve systems
EX closeControl of internal EGR
IN openControl of pumping lossNOL
IN close Control ofeffective compression ratio
EX IN
VTCVTC VTCVTC
360360-360-360 -270-270 -180-180 -90-90 00 9090 180180 270270
Temperature controlEX openControl ofblow down loss
Crank angle (deg)
4. Results of Verification of ConceptThe SA-HCCI system discussed above was tested in a
4-cylinder engine. Table 1 shows the specifications of the engine used in verification.
4.1. Verification of Controllability of Ignition Timing Figure 13 shows the results of comparison of the
controllability of ignition in HCCI and SA-HCCI at an Ne of 1500 rpm and an IMEP of 420 kPa. The verification compared the combustion range when the in-cylinder
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Honda R&D Technical Review October 2014
-5
5
15
25
35
45
55
-30 -20 -10 0 10 20 30
dQ (J
/deg)
Crank angle (deg)
SA-HCCI (IG=10 deg BTDC)
SA-HCCI (IG=30 deg BTDC)SA-HCCI (IG=20 deg BTDC)
HCCI
Fig. 14 Comparison of heat release rates
Fig. 15 Comparison of combustion range
35
40
45
50
55
60
65
70
250 350 450 550
EGR
limit
(%)
IMEP (kPa)
SA-HCCIHCCI
At the same time, an increase in NOx emissions was also observed as a result of the increase in the combustion amount for the trigger flame. The status of SA-HCCI can also be expressed by the waveforms of the heat release rate, dQ, as shown in Fig. 14. The results show that a trigger flame combusts prior to auto-ignition and that the advancement of ignition timing has expanded combustion of the trigger flame in comparison to HCCI.
Figure 15 shows the results of verification of the combustion range under various load conditions. The results show that SA-HCCI has a greater effect than HCCI at all loads.
As the results discussed above indicate, by increasing the controllability of ignition, SA-HCCI has increased the combustion range in relation to the amount of EGR by two to three times against HCCI.
4.2. Verification of Steady-state Fuel Consumption Figure 16 shows a comparison of the results of fuel
consumption and NOx measurements at an Ne of 1500 rpm for SA-HCCI and stoichiometric SI combustion. Table 2 shows the main specifications of the technologies under comparison. Based on indexes for commercial appeal, the upper limit for the operating range of SA-HCCI was a brake
Table 2 Engine specifications
Stoichiom-etry
Atkinsoncycle
CooledEGR SA-HCCI
Number ofcylinders 4 4 4 4
Displacement[cm3] 1.8 1.8 1.5 1.5
Compressionratio 11 13 13 14
EGR None Hot15%Cooled
25%Internal30-60%
Gasoline 91RON 91RON 91RON 91RON
Fig. 16 Results for 4-cylinder engine
0
0.1
0.2
0.3
NO
x (m
g/s)
100 200 300 400 500 600
BSFC
(g/kW
h)
BMEP (kPa)
dP/d
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Advanced Ignition Control Technology for HCCI Combustion
Among the main factors in this are an increase in theoretical thermal efficiency (as a result of an increase in the ratio of specific heat due to increased leanness and the dilution of EGR, and the expansion of the compression ratio) and a reduction in heat loss. In the future, further increases in fuel efficiency can be expected as a result of efforts to reduce the pressure rise rate and expand the range of operating loads.
With regard to NOx emissions, figures are low in the area below 300 kPa, but as load increases emissions increase rapidly. In the low-load area, because the gas temperature of the main combustion area is low, NOx is only produced by the trigger flame; however, as the gas temperature of the main combustion area increases with increasing load, it also produces NOx. At present, emissions exceed the level that would clear the established target of a 75% reduction in NOx emissions, as specified by Japans Post New Long-Term Regulation, with operation up to a maximum load point of BMEP 400 kPa as a prerequisite. The use of lean NOx catalysts in order to maximize the increase in fuel efficiency offered by SA-HCCI will be considered, and operation up to a BMEP of 400 kPa is projected.
4.3. Results of Verification using JC08 Mode Fuel Efficiency Simulation
A verification of the system was conducted using a JC08 mode fuel efficiency simulation, based on the current SA-HCCI operating range and results for steady-state fuel consumption performance. Table 3 shows the main specifications of the vehicle used in the simulation. The mode fuel efficiency of cooled EGR combustion and cooled EGR combustion with SA-HCCI combustion were compared.
Figure 18 shows the simulation results. The results show that the addition of SA-HCCI to the cooled EGR technology increases fuel efficiency by approximately 4.5%.
5. Conclusion A development with a focus on the controllability of
ignition was conducted towards the practical realization of HCCI, with the following results. (1) SA-HCCI was developed to assist HCCI ignition
using direct injection in an attempt to increase the controllability of ignition. Verification of the concept showed that it expanded the combustion range by two to three times against conventional HCCI.
(2) The fuel eff ic iency of SA-HCCI was ver i f ied, demonstrating that the system reduced steady-state fuel consumption by approximately 16% against cooled EGR. Simulation verification of JC08 mode fuel efficiency indicated that an increase of approximately 4.5% in fuel efficiency could be expected.
References
(1) Wang, C., Daniel, R., Xu, H.: Research of the Atkinson Cycle in the Spark Ignition Engine, SAE Technical Paper, 2012-01-0390 (2012)
(2) Lecointe, B., Monnier, G.: Downsizing a Gasoline Engine Using Turbocharging with Direct Injection, SAE Technical Paper, 2003-01-0542 (2003)
(3) Aoyama, T., Hattori, Y., Mizuta, J., Sato, Y.: An Experimental Study on Premixed-Charge Compression Ignition Gasoline Engine, SAE Technical Paper, 960081 (1996)
(4) Hiraya, K., Hasegawa, K., Urushihara, T., Iiyama, A., Itoh, T.: A Study on Gasoline-Fueled Compression Ignit ion Engine A Trial of Operation Region Expansion, SAE Technical Paper, 2002-01-0416 (2002)
(5) Fuerhapter, A., Piock, W. F., Fraidl, G. K.: CSI-Controlled Auto Ignition the Best Solution for the Fuel Consumption Versus Emission Trade-Off?, SAE Technical Paper, 2003-01-0754 (2003)
(6) Koopmans, L., Strom, H., Lundgren, S., Backlund, O., Denbratt, I.: Demonstrating a SI-HCCI-SI Mode Change on a Volvo 5-Cylinder Electronic Valve Control Engine, SAE Technical Paper, 2003-01-0753 (2003)
(7) Urata, Y., Awasaka, M., Takanashi, J., Kimura, N.: Study on Gasoline HCCI Engine Equipped with Electromagnetic Variable Valve Timing System, Aachener Kolloquium Fahrzeug- und Motorentechnik (2004)
(8) Kuboyama, T., Moriyoshi, Y., Hatamura, K., Yamada, T., Takanashi, J., Fujii, N., Urata, Y.: A Study of HCCI (Homogeneous Charge Compression Ignition) Gasoline Engine Supercharged by Exhaust Blow-Down Pressure, JSAE Annual Congress Proceedings, No. 124-08, p. 7-10 (2008) (in Japanese)
(9) Kamio, J. , Kurotani, T., Sato, T., Kiyohiro, Y., Hashimoto, K., Gunji, T.: A Study on Combustion Control by Dual-Fuel Strategies, JSAE Annual Congress Proceedings, No. 55-07, p. 19-22 (2007) (in Japanese)
Table 3 Specifications of simulated carCar FIT
Weight [kg] 968Displacement [cm3] 1500
Transmission CVT
Fig. 18 Simulation results
110
112
114
116
118
120
Cooled EGR+SA-HCCICooled EGR
CO2
em
issi
ons
(g)
4.5%
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Honda R&D Technical Review October 2014
(10) Yamamoto, Y., Sato, G., Hayashi, T.: Development of Cylinder Pressure Sensor Integrated with Direct Injector, Honda R&D Technical Review, Vol. 24, No. 1, p. 55-59
Author
Kiminori KOMURA Masanobu TAKAZAWA Teruyoshi MORITA
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